Indoor navigation and tracking with mesh network

ABSTRACT

This application discloses systems, devices, and methods for indoor navigation and tracking with a mesh network. In one aspect, a navigation device includes a receiver configured to receive a locational signal from a node network. The locational signal identifies a respective node of the node network, and the node network is distributed throughout a physical space. The navigation device includes a memory storing a program and a processor in communication with the receiver and configured to execute the program to calculate a position of the navigation device from the identity of the respective node, determine a routing instruction from the position of the navigation device to a destination based on the position of the navigation device and a known mapping of the node network in the physical space, and update the position of the navigation device and the routing instruction as the navigation device moves through the physical space.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuing application of U.S. patent applicationSer. No. 16/743,854 filed on Jan. 15, 2020, which application is herebyincorporated herein by reference.

TECHNICAL FIELD

The present invention relates generally to systems and methods fornavigation and tracking, and, in particular embodiments, to indoornavigation and tracking with a mesh network.

BACKGROUND

While global positioning system (GPS) is good at providing locationinformation while outdoors, indoor navigation and tracking is notpossible using GPS because of the shielding of GPS signals by largebuildings. This is also true in many cases with tracking or navigationsystems based on signals received and transmitted utilizing mobilenetworks. Signals cannot easily penetrate malls, stadiums, schools, orother indoor facilities. This can hamper efforts to track/navigatewithin those spaces or adversely impact tracking or navigation accuracy.The same can be said for any location where signal transmissions areobscured or blocked.

There are many places where indoor navigation/tracking is desirable andimprovements in indoor tracking/navigation devices are desirable.Accurate navigation within supermarkets and shopping complexes may helpconsumers locate stores, sections, or even items. Tracking within thesesame facilities may help businesses collect data about shopping habits,locating inventory, employees, or customers. Navigation within airportscan help travelers find a desired gate, bathroom, or other locationwithin an airport. Tracking can be used to locate lost equipment orpeople. There are many instances where indoor tracking can beapplicable, for example, in regular use, for helping inaccessiblepersons in case of emergency or calamities. Factories can benefit totrack workers and used by workers to locate equipment.

SUMMARY

In accordance with an embodiment of the present invention, a navigationsystem includes a node network that includes a plurality of nodesdistributed throughout a physical space. The plurality of nodes isconfigured to emit a plurality of locational signals from a plurality ofemitting nodes, where the plurality of locational signals identifies theplurality of nodes. The navigation system further includes a map of thephysical space including the locations of the plurality of nodes. Thenavigation system further includes a navigation device that includes areceiver configured to receive a locational signal transmitted by arespective emitting node of the plurality of nodes in a communicationrange of the navigation device. The navigation device further includes amemory storing a program and a processor in communication with thereceiver and configured to execute the program to access the map of thephysical space, calculate a position of the navigation device in thephysical space from the locational signal received by the navigationdevice, and determine a routing instruction from the position of thenavigation device to a destination based on the position of thenavigation device and the mapping of the physical space.

In accordance with an embodiment of the present invention, a system fortracking a device in a physical space includes a tracking devicedisposed at a position in the physical space. The tracking deviceincludes a transmitter configured to transmit a beacon signal thatidentifies the tracking device. The system includes a node networkincluding a plurality of nodes, where the nodes of the plurality ofnodes are configured to receive the beacon signal when in acommunication range of the tracking device. The system also includes amap of the physical space including locations of the nodes of theplurality of nodes. The tracking device further includes a memorystoring a program and a processor in communication with the node networkand the memory. The processor is configured to execute the program toidentify the position of the tracking device by retrieving datatransmissions from the plurality of nodes that indicate when the nodesof the plurality of nodes are in the range of the tracking device.

In accordance with an embodiment of the present invention, a method fornavigation within a physical space includes emitting locational signalsfrom a node network distributed throughout a physical space, where thelocational signals identify the nodes of the node network. The methodfurther includes receiving one of the locational signals at a navigationdevice emitted from a node of the node network in a communication rangeof the navigation device. The method further includes calculating aspatial position of the navigational device from an identity of the nodeof the node network in the communication range of the navigation device.The method further includes determining a routing instruction from theposition of the navigational device to a selected destination in thephysical space.

In accordance with an embodiment of the present invention, a method fortracking a device within a physical space includes mapping a nodenetwork within the physical space; emitting a beacon signal from atracking device at a location in the physical space; receiving thebeacon signal at a plurality of nodes of the node network in acommunication range of the tracking device; communicating an identity ofthe nodes in the communication range of the tracking device to aprocessor; and determining a spatial position of the tracking device bythe processor from the identity of the nodes in the range of thetracking device.

BRIEF DESCRIPTION OF THE DRAWINGS

For a more complete understanding of the present invention, and theadvantages thereof, reference is now made to the following descriptionstaken in conjunction with the accompanying drawings, in which:

FIG. 1 illustrates a diagram of a node network;

FIG. 2 illustrates a diagram of an embodiment of a navigation device;

FIG. 3 illustrates a diagram of an embodiment of a navigation system;

FIG. 4 illustrates an embodiment of a tracking device;

FIG. 5 illustrates a diagram of an embodiment of a tracking system;

FIG. 6 illustrates a block diagram of a method of navigation; and

FIG. 7 illustrates a block diagram of method of tracking.

Corresponding numerals and symbols in the different figures generallyrefer to corresponding parts unless otherwise indicated. The figures aredrawn to clearly illustrate the relevant aspects of the embodiments andare not necessarily drawn to scale.

DETAILED DESCRIPTION OF ILLUSTRATIVE EMBODIMENTS

The making and using of embodiments of this disclosure are discussed indetail below. It should be appreciated, however, that the conceptsdisclosed herein can be embodied in a wide variety of specific contexts,and that the specific embodiments discussed herein are merelyillustrative and do not serve to limit the scope of the claims. Further,it should be understood that various changes, substitutions andalterations can be made herein without departing from the spirit andscope of this disclosure as defined by the appended claims.

Conventional ideas for tracking/navigation indoors or in obscuredlocations involve beacon technologies to help track people usingdedicated scanners and beacon generators. The fixed location of suchbeacons and scanners help to locate and navigate. However, suchdedicated scanners are of limited use when dealing with new locations oraddressing a large population effectively.

Currently, there is no known standard available for indoornavigation/tracking. But, one system for navigation/tracking indoors andin obscured places may utilize a node network to transmit and receivesignals. The nodes themselves may be located indoors or in obscuredareas where signals in other technologies have difficulty penetrating.And, nodes may be easily added, removed, or moved through the system.

One such system may utilize mesh networking. Mesh networking ofappliances is an emerging technology. More and more buildings and socialplaces will have mesh networks comprising a wide variety of lights,sensors, displays, equipment, machinery and appliances configured tooperate as a node of the network.

Using mesh networking allows data to travel along multiple pathwaysbetween any two nodes along routes from any of the other nodes in thenetwork. This can reduce the reliance of the system on any centralrouting unit or units. Plus, the presence of nodes that can generate andreceive signals inside a mall, shopping center or other facility allowssignals to penetrate areas with otherwise limited accessibility. It,also, is not necessary to have such a network connected to outsidesystems. In other words, mesh networks can be self-contained, which canbe desirable for security purposes.

Bluetooth Mesh is one type of mesh networking and is a wirelessstandard. Its primary application is in smart buildings. It featuresmany to many nodes connectivity where all nodes are reachable from anyother node. There is no limit to the number of mesh nodes present in aBluetooth Mesh network. A Bluetooth Mesh controlled smart building wouldhave hundreds or thousands of mesh nodes catering to differentapplications such as smart lights: lights in corridors, wash rooms,shops, supermarkets; sensor nodes: temperature sensors, environmentalsensors; smart switches: switches to control lights in their vicinitylike normal switches; smart equipment: HVAC, smart plug, smartregulators; and emergency nodes. Other equipment and appliances likecoffee makers, crock pots, blenders, televisions, monitors and virtuallyany electronic device may be a Bluetooth Mesh enabled node. BluetoothMesh has multi-layer and multi-application configurable security levelsto address different scenarios and known security challenges. BluetoothMesh provides flexibility to users, which makes it a leading choice forsmart home/smart building applications where high data throughput is notnecessarily a priority.

With Bluetooth Mesh gaining popularity around the world and expected toreach billions of nodes, Applicant proposes to address indoor navigationand tracking using mesh technologies such as Bluetooth Mesh in a costeffective manner. It should be noted that the applications of thepresent invention are not limited to Bluetooth Mesh networks.

Embodiments of the present application disclose devices, systems andmethods for tracking and navigation within a physical space. Anembodiment node network that can be used for tracking and navigationwill be described in FIG. 1. FIGS. 2 and 3 further describe embodimentsof the navigation device and navigation system. FIGS. 4-5 furtherdescribe embodiments of the tracking device and tracking system. Atracking method will be described using FIG. 6 while a navigationalmethod will be described using FIG. 7.

FIG. 1 illustrates an embodiment of a node network 9 in a physical space20 that is in the interior of a building, warehouse, mall, or otherstructure. In various embodiments, the node network 9 is distributedthroughout the physical space 20. It should also be appreciated that inembodiments the node network 9 may not be confined to an interior space.For example, a node network 9 may be located on a street, a town, apark, campus, on a ship, or a backyard. The node network 9 may bepartially indoors and partially outdoors. The physical space 20 may alsocomprise a physical space 20 located on multiple floors of a structureor multiple rooms. The node network 11 may be located in any place wherethe nodes may be placed.

The node network 9 comprises a plurality of nodes 10. The nodes of theplurality of nodes 10 may comprise different forms in differentembodiments. Nodes may be smart devices like smart switches, or smartappliances. Nodes can also be sensors, cameras, mobile devices, wearablebuttons or tokens, or dedicated nodes. Virtually any electronic devicecan also be configured to be a node of the node network 9. In someembodiments, a single device may comprise the plurality of nodes 10.

In embodiments, the node network 9 may comprise a variety of differenttypes of nodes. Some of the plurality of nodes 10 of the node network 9may be switches, some of the plurality of nodes 10 of the node network 9may be lights, some of the plurality of nodes 10 of the node network 9may be sensors, and some of the plurality of nodes 10 of the nodenetwork 9 may be smart appliances. The node network 9 may comprise anycombination of different types of nodes. In some embodiments, nodes 10of the node network 9 are configured for node to node communication.

The node network 9 may comprise a mesh network in one exampleembodiment. In some embodiments, each node in the node network 9 may beconfigured to relay transmissions to and from the other nodes in thenode network 9 that are in range of the transmitting nodes. In this way,data signals may be relayed from any one of the nodes 10 in the networkto any or all the other nodes in the node network 9. Messages and, or,signals, may be relayed in the node network 9 by a flooding or managedflooding. In various embodiments, the node network 9 may be configuredfor many to many communications between the nodes of the node network 9.Data from any node in the node network 9 may also be accessed from anyother point in the network. In some embodiments, the node network 9comprises a Bluetooth Mesh network.

In some embodiments, the nodes of the node network 9 may also beaddressable so that data transmissions can be relayed through the nodenetwork 9 to them. For example, a data transmission may be addressed tonode 10D of the plurality of nodes 10. In embodiments, node 10D maycomprise a smart locking device. A message relayed through the nodenetwork 9 may direct node 10D to lock. The message may be addressed tonode 10D individually so that node 10D will implement the direction tolock but no other nodes.

In some embodiments, the nodes of the plurality of nodes 10 may beaddressable as a subgroup of the plurality of nodes 10. For example,nodes 10A, 10B, 10C and 10D may comprise smart locks in someembodiments. A message may be directed to all locks in the node network9 to become unlocked. Nodes 10A, 10B, 10C and 10D will receive themessage and follow the command while other nodes of the node networkwill not follow the command. The plurality of nodes 10 can be dividedinto any manner of groups in different embodiments depending on theneeds of the node network 9.

In some embodiments, a subset of nodes of the plurality of nodes 10 isconfigured to relay or transmit data. Relay nodes may receive data andtransmit data to other nodes of the plurality of nodes 10. While othernodes, may only transmit data. In an embodiment, nodes 10A, 10B, 10C and10D comprise relay nodes whereas nodes 10X, 10Y, and 10Z do not. Thiscan be advantageous in some embodiments for reducing the powerrequirements of the node network 9 while still allowing communicationbetween all the nodes of the network. Any of the nodes of the nodenetwork 9 may comprise relay nodes in different embodiments. And, insome embodiments, all nodes of the node network 9 may comprise relaynodes. In some embodiments, non-relaying or non-transmitting nodes maycomprise Bluetooth Low Energy devices.

In various embodiments, messages or signals relayed between the nodes 10may comprise a time to live (“TTL”) indicator or value. The time to liveindicator may limit the dissemination of data through the network.Messages may be initialized with a given TTL. After the message isrelayed to another node, the TTL is decremented. Messages with a valuebelow a given threshold will not be relayed.

For example, each message in a node network 9 may contain a TTL fieldand the TTL field indicates how the message should be relayed as well asproviding some information about the history of the message in the nodenetwork 9. The table (Table I) below illustrates an embodiment.

TABLE I TTL Relay VALUE Direction Historical Implication 0 Do no relayMessage cannot be relayed and the sender of the message is theoriginator 1 Do not relay Message has been relayed in the past butcannot be relayed further 2-127 Relay Message should be relayed

In another example, in one embodiment, a message may be initialized witha TTL of 3 and the system may be configured to not relay the message ifthe TTL reaches below 1. Thus, such a message can be received at a node10A with a TTL of 3, and next relayed to a node 10B with a TTL of 2, andnext relayed to a node 10C with a TTL of 1, which does NOT relay to anode 10D with a TTL of 0. Since the TTL is 1 (threshold for relaying) atthe node 10C, it will not be forwarded to any other node.

Accordingly, one proposed embodiment is based on using messages withTTL=0 to determine the originating node. Both navigation and trackingapplications may be based on same underlying concept. A sender publishesmesh message with TTL=0 with some additional details. The message isreceived by all mesh nodes (of same network) in direct range of thesender node. Because TTL=0 for the received message, receiver node canestablish that sender has originated this message (not relayed thismessage).

In embodiments wherein nodes emit messages initialized with TTL=0,messages are only received by nodes in the range of the initial signal.As mentioned, this information can be used to establish the originatorof the message. And, it also prevents messages from being distributedthroughout the node network limiting any impact on the node network.

In some embodiments, a tracking device may emit a tracking signal orbeacon signal. This signal may also be initialized with TTL=0. In suchembodiments, receiving nodes will not transmit the beacon signal.Receiving nodes may also determine that they are the original receptorof the message by the TTL value.

When receiving locational signals with a TTL=0 value, receiving nodescan determine that they are in range of the tracking device. Similarly,a navigation device can determine that it is in the range of a node whenit receives a locational signal from a respective node with a TTLvalue=0. Only nodes in the vicinity of the tracking device will receivethe signal because they will not be retransmitted through the network.And, this information can be used to follow the path of the trackingdevice through the node network. In embodiments, the receiving nodestores this information in its database for future use. This informationneed not be communicated instantaneously.

For navigation applications, a navigation device, which has received asignal from a node, may apply a navigational algorithm for human basedunderstanding of current location or path to be followed to a finaldestination. Navigation, tracking and combinational embodiments of thepresent invention are described further below.

FIG. 2 illustrates an embodiment of a navigation device 200 that may beused for navigational applications in a node network. In variousembodiments, the navigation device 200 comprises a receiver 201 with anantenna 202 and receiver circuit 204. In some embodiments, thenavigation device comprises a user interface 206, a processor 208, andmemory 210 comprising instructions to be executed in the processor 208.

In various embodiments, the receiver 201 is configured to receive alocational signal from a node network 9 (shown in FIG. 1). And, thereceiver 201 is in communication with the processor 208. In variousembodiments these various components can take any variety of forms knownin the art.

In some embodiments, the navigation device 200 may comprise a mobilephone, smart phone, tablet, laptop computer, watch, or other device withan application to run a navigation program. In other embodiments, thenavigation device 200 may comprise a dedicated navigation device for usein a specific node network of type of node network. In some embodiments,the navigation device 200 may also function as a node of the pluralityof nodes 10 of the node network 9.

The navigation device 200 (or the program being executed) may beconfigured to operate along with a cloud based program and informationreceived from the node network 9 to provide navigation to the user.

FIG. 3 illustrates an embodiment of a navigation device 200 in a nodenetwork 9. FIG. 3 depicts an enlarged portion of the node network 9 andphysical space 20 depicted in FIG. 1. The node network 9 in FIG. 3 maycomprise any of the embodiments of the node network 9 in FIG. 1.

Returning to FIG. 3, in various embodiments, the navigation device 200receives a locational signal 302A identifying an emitting node 302 ofthe node network 9. The emitting node 302 may take any embodiment ofnode of the plurality of nodes 10 described with reference to FIG. 1. Insome embodiments, the locational signal 302A is emitted by the emittingnode 302 only when the navigation device 200 is in a range of theemitting node 302.

The navigation device 200 may comprise a memory 210 (from FIG. 2)storing a program and a processor 208 (from FIG. 2). The processor 208of the navigation device 200 may be in communication with the receiver201 of the navigation device 200. The processor 208 of the navigationdevice 200, in various embodiments, is configured to execute the programto: calculate a position of the navigation device 200 in the physicalspace 20 from the identity of the emitting node 302 and a known mappingof the node network 9 in the physical space 20. The program whenexecuted by the processor 208 determines a routing instruction from theposition of the navigation device 200 to a destination 308 based on theposition of the navigation device 200, and updates the position of thenavigation device 200 and the routing instruction as the navigationdevice 200 moves through the physical space 20.

In various embodiments, a user of the navigation device 200 may select adestination 308 for navigation. The destination 308 may compriselocations within the physical space 20 such as a store in a mall or aterminal in an airport. The destination 308 may also be provided to thenavigation device 200 instead of being received from a user. In variousembodiments, the destination 308 may comprise a node of the node network9. In various embodiments, the destination 308 may comprise a devicebeing tracked through the physical space 20. And, in some embodiments,the destination 308 may comprise a location or coordinates in thephysical space 20.

In various embodiments, the processor 208 has access to the mapping ofthe physical space 20. In various embodiments, the known mapping may bestored in the memory 210 of the navigation device 200. In suchembodiments, the known mapping may be configured to be updated toreflect changes in the node network 9 such as node movement, or nodesbeing added to or removed from the node network 9. In some embodiments,updates may occur when the navigation device is connected to a cloudnetwork. In some embodiments, the processor 208 may access a knownmapping that is not stored on the navigation device 200. The knownmapping may be stored in a data cloud accessible by the navigationdevice or a central memory. The known mapping may be updatedperiodically in some embodiments or, in real time. In some embodiments,the navigation device 200 may be configured to connect to a networkoutside the node network 9. In some embodiments, the navigation device200 may not be capable of connecting to other networks.

In some embodiments, the locational signal 302A may identify node a 302only by the position of the emitting node 302. The locational signal302A may comprise data that directly identifies the position of emittingnode 302, such as coordinates, or data that can be used to derive thelocation of the emitting node 302. In various embodiments the node maybe identified by a Bluetooth Device Address, Universal UniqueIdentifier, MAC ID, or another manner for uniquely identifying the nodes10 of the node network 9. In various embodiments, coordinates of thenode may comprise longitudinal/latitudinal coordinates, coordinatesdesigned for the physical space 20, or other form known in the art. Thelocational signal 302A may comprise information that identifies thelevel of the physical space 20 where the emitting node 302 is located,the room, or other locational characteristic. The physical space 20 maybe mapped to zones and the locational signal 302A may identify the zonewhere the emitting node 302 is located. In various embodiments, eachzone may correspond to a level or room or other space. The locationsignal 302A may also the include relative location of a node so as todetermine the surroundings and/or meta information such as other relatedinformation.

In some embodiments, the locational signal 302A may comprise a TTLvalue. The TTL value may be set to zero. In various embodiments, thenode network 9 will not relay locational signal 302A because it has aTTL value set to 0. In such embodiments, any node or device, forexample, navigation device 200, that receives the locational signal 302Amay be able to determine from the TTL value of 0 that the locationalsignal 302A originated at the emitting node 302. In this way, the nodenetwork may prevent the locational signal of the plurality 302A frombeing relayed by the plurality of nodes 10 when the locational signalcomprises a TTL value set to 0. In some embodiments, the navigationdevice 200 may be configured so that only locational signals comprisinga TTL value of 0 are received by the receiver 201. In some embodiments,the program executed by the processor 208 may only consider locationalsignals that comprise a TTL value set to o to determine the location ofthe navigation device 200.

In some embodiments, the routing instructions may comprise a sequence ofinstructions. In some embodiments, the user interface 206 of thenavigation device 200 is in communication with the processor 208 andconfigured to provide the routing instruction. In various embodiments,routing instruction may be provided by visual, audio, tactile means, orother means.

In some embodiments, at least one of the nodes of the node network 9 islocated indoors. In some embodiments, all the nodes of the node network9 may be indoors. And, in some embodiments, some of the nodes of thenode network 9 may be indoors and some may be outdoors.

In some embodiments, each node of the node network 9 emits a locationalsignal that identifies the node. For example, the first locationalsignal 302A received by the receiver 201 of the navigation device 200comprises the locational signal emitted by the first emitting node 302.Second and third locational signals 304A and 306A are emitted fromsecond and third emitting nodes 304 and 306 respectively.

Although only the second and the third locational signals 304A and 306Aare referenced herein, in embodiments each node of the plurality ofnodes 10 may emit locational signals. Other locational signals maycomprise any embodiment of the second and the third locational signals304A, 306A described. In some embodiments, some nodes of plurality ofnodes 10 may emit locational signals while other nodes may not.

In some embodiments, the second and the third locational signal 304A and306A of each node comprises data indicating the position of the secondemitting node 304 and the third emitting node 306 in the physical space20 that originated the locational signal 304A and 306A. The identifyingsecond and the third location signals 304A, 306A may comprise anyembodiment of the first locational signal 302A. In some cases, all theidentifying locations signals of the node network 9 may have the samecommunication range. However, in some embodiments, different locationalsignals may have different communication ranges.

The receiver 201 of the navigation device 200 may be configured toreceive additional second and the third locational signals 304A, 306Aand the position of the navigation device 200 may be further calculatedfrom the identities of the second and the third emitting nodes 304, 306identified by the additional second and the third locational signals304A, 306A.

As depicted in FIG. 3, the navigation device 200 is located within therange of the first, the second, and the third locational signals 302A,304A, and 306A. Being in range of these signals, the receiver 201 of thenavigation device may receive each of the first, the second, and thethird locational signals 302A, 304A, and 306A. The navigation device 200may also receive locational signals from any other node of the nodenetwork 9 when it is in the range of the node.

Having received the first, the second, and the third locational signals302A, 304A, 306A that respectively identify the first, second, thirdemitting nodes 302, 304, 306 where they originated, the processor 208 ofthe navigation device 200 can run a program stored in its memory 210 todetermine where the navigation device 200 is in the physical space. Invarious embodiments, this can be accomplished in a variety of ways.

In some embodiments, the known mapping may divide the physical space 20into areas so that each area in the physical space 20 is identifiable bythe locational signals that overlap in that area. The program executedby the processor 208 may compare the locational signals received by thenavigation device 200 with the known mapping and determine which areathe navigation device is located. For example, in FIG. 3, the first, thesecond, and the third locational signals 302A, 304A, and 306A overlap atthe area 312. When the processor 208 recognizes that these three signalshave been received by the navigation device 200, it can determine thatthe navigation device 200 is located in the area 312. In someembodiments, the first, the second, and the third locational signals302A, 304A, and 306A may just identify the first, second, third emittingnodes 302, 304, 306 by their position in the physical space 20. Theposition of the first, second, third emitting nodes 302, 304, 306 ofplurality of nodes 10 may be defined by coordinates or other markers. Aswill be appreciated, the navigation device 200 may be configured toreceive a large number of locational signals. This may improve theaccuracy and reliability of the navigation. In embodiments each area maycorrespond to a space wherein an unique combination of locationalsignals overlap.

In some embodiments, the navigation device 200 may be able detect thesignal strength of the first, second, third locational signals 302A,304A, 306A received by the navigation device. The program executed bythe processor 208 may input the signal strengths of the first, second,third locational signals 302A, 304A, 306A into a multilaterationalgorithm to determine the position of the navigation device 200 in thephysical space 20. The multilateration algorithm, in variousembodiments, may also use the known mapping of the corresponding first,second, third emitting nodes 302, 304, 306 to determine the position ofthe navigation device 200.

In some embodiments, the navigation device 200, may be configured todetect the Angle of Arrival of the first, second, third locationalsignals 302A, 304A, 306A received at the navigation device 200. Theprogram executed by the processor may input the Angle of Arrival into atriangulation algorithm to calculate the position of the navigationdevice 200 in the physical space 20. The triangulation algorithm, invarious embodiments, may use the known mapping of the correspondingfirst, second, third emitting nodes 302, 304, 306 to determine theposition of the navigation device. The different ways to determine thelocation of the navigation device may also be used in variouscombinations with each other, in some embodiments, to improve accuracy.

In some embodiments, the receiver 201 may comprise an array of antennas.

In some embodiments, the nodes of the plurality of nodes 10 continuouslyemit (broadcast) the first, the second, and the third locational signals302A, 304A, and 306A. As the navigation devices passes in and out of theranges of different locational signals, the position of the navigationdevice 200 can be updated accordingly. In some embodiments, updates mayoccur in real time. In other embodiments updates may occur periodically.In some embodiments, updates may be triggered when the navigation device200 passes out of the range of a locational signal or into the range ofa locational signal. In some embodiments, updates may be directed by auser.

Referring to FIGS. 1, 2, and 3, embodiments of a navigation system 300comprises a node network 9 comprising a plurality of nodes 10distributed throughout a physical space 20, wherein the plurality ofnodes 10 is configured to emit a plurality of first, second, thirdlocational signals 302A, 304A, 306A from a plurality of first, second,third emitting nodes 302, 304, 306, and wherein the plurality of first,second, third locational signals 302A, 304A, 306A identify the pluralityof first, second, third emitting nodes 302, 304, 306.

In various embodiments, the navigation system 300 further comprises amapping of the physical space 20 comprising the locations of theplurality of nodes 10. The navigation system 300 may further comprisethe navigation device 200 comprising a receiver 201 configured toreceive a locational signal 302A emitted by a first emitting node 302 ofthe plurality of nodes 10 in a communication range of the navigationdevice 200; a memory 210 storing a program; and a processor 208 incommunication with the receiver 201 and configured to execute theprogram to access the mapping of the physical space 20, calculate aposition of the navigation device 200 in the physical space 20 from thefirst locational signal 302A received by the navigation device 200, anddetermine a routing instruction from the position of the navigationdevice 200 to a destination 308 based on the position of the navigationdevice 200 and the mapping of the physical space 20.

In some embodiments each node of the plurality of nodes 10 of the nodenetwork 9 emit a first, second, and third locational signal 302A, 304A,306A that identifies the first, the second, and the third emitting node302, 304, 306 from which it was emitted, and wherein the firstlocational signal 302A received by the receiver 201 comprises the firstlocational signal 302A emitted by the first emitting node 302.

In some embodiments, the first, the second, and the third locationalsignal 302A, 304A, 306A of each of the first, the second, and the thirdemitting nodes 302, 304, 306 comprises data indicating the position ofthe corresponding first, second, and third emitting nodes 302, 304, 306from which it was emitted in the physical space 20.

In some embodiments, the receiver 201 is configured to receive thesecond and the third locational signals 304A, 306A in addition to thefirst locational signal 302A. And, wherein the position of thenavigation device 200 is further calculated from the identities of thesecond and the third emitting nodes 304, 306 identified by theadditional second, third locational signals 304A, 306A.

In some embodiments, the first, second, third emitting nodes 302, 304,306, of the node network 9 continuously emit first, second, thirdlocational signals 302A, 304 a, and 306A.

In addition to navigational applications, embodiments of the inventionof this disclosure may also allow tracking applications.

FIG. 4 of the present application illustrates an embodiment of atracking device 400. The tracking device 400 may comprise a transmitter403 with an antenna 402 to transmit a beacon signal that identifies thetracking device 400. The tracking device may be a wearable device thatmay periodically send message or beacon signal to be picked up by nearbyfixed nodes configurable to process such messages. Fixed nodes may storethis information (neighbor information) in its database which can beshared if required.

In some embodiments, the tracking device 400 may comprise a mobilephone, tablet, laptop, smart appliance, or node 10 of a node network 9.The previously described navigation device 200, in some embodiments mayalso comprise a tracking device 400. In some embodiments, the trackingdevice 400 may comprise a processor 406 and a memory 408 incommunication with the memory. The memory 408 may comprise a program tobe executed in the processor 406.

FIG. 5 of the present application illustrates an embodiment of atracking system 500. Tracking device 400 is disposed at a position inthe physical space 20. The tracking system 500 further comprises a nodenetwork 509 comprising a plurality of nodes 510. In some embodiments,the node network 509 may comprise the node network 9 of FIGS. 1 and 3.And, the node network 509 may comprise any embodiment of the nodenetwork 9. For example, the node network 509 may comprise a mesh networkin some embodiments. The node network 509 may also comprise a BluetoothMesh network or other node networks known in the art. The plurality ofnodes 510 may comprise the plurality of nodes 10 of FIGS. 1 and 3 andmay comprise any embodiment of the plurality of nodes 10.

As depicted in FIG. 5, the tracking device 400 may transmit a beaconsignal 400A. In some embodiments, the plurality of nodes 510 isconfigured to receive the beacon signal 400A when in a communicationrange of the tracking device 400. For example, in the embodimentdepicted in FIG. 5, nodes 514, 514A, 514B and 514C are in the range ofthe beacon signal 400A. Being in the communication range, these nodes514, 514A, 514B and 514C may receive the beacon signal 400A.

In some embodiments, the beacon signal 400A may be initialized with aTTL value of 0. This will prevent the beacon signal 400A from beingrelayed through the node network 509 after it is received by a node ofthe plurality of nodes 510. And, receiving nodes, such as 514, 514A,514B and 514C in the embodiment depicted in FIG. 5, can determine thatthe tracking device 400 originated the beacon signal 400A because thebeacon signal has a TTL value set to 0.

The tracking system 500 may further comprise a mapping of the physicalspace 20. The mapping may be in a digital form in some embodiments. Insome embodiments the mapping may comprise a database of the plurality ofnodes 510 and their coordinates. The mapping may be comprise anyembodiments of the known mapping of the navigation system and may beupdated in any of the same ways as the known mapping of the navigationsystem.

In some embodiments, the tracking system 500 may further comprise amemory 518 storing a program; and a processor 520 in communication withthe node network 509 and the memory 518, the processor 520 beingconfigured to execute the program to: identify the position of thetracking device 400 by retrieving data transmissions from the pluralityof nodes 510 that indicate when the nodes of the plurality of nodes 510are in the range of the tracking device 400. Some of the processing maybe performed locally while some of the processing may be performed inthe cloud, accordingly, the processor 520 and the memory 518 may belocal and/or in the cloud.

As an example, in some embodiments, like depicted in FIG. 5, nodes 514,514A, 514B and 514C in the range of tracking device 400 may receive thebeacon signal 400A. The processor 520 can execute a program to retrievethis information from the node network 9. Having determined that thetracking device 400 is in the range of nodes as 514, 514A, 514B and514C, the processor can then identify the location of the trackingdevice 400 in the physical space.

In various embodiments, the position of the tracking device can beaccomplished in a variety of ways. In some embodiments, the combinationof nodes in the range of the tracking device may be corresponded to anarea in the physical space based on the positions of the known positionsof the nodes in range of the tracking device 400. This could beaccomplished with a lookup table. In some embodiments, the location ofthe tracking device may also be determined geometrically based on thelocation of the nodes that are in range of the navigation device.

In some embodiments, the mapping may divide the physical space 20 intoareas so that each area in the physical space 20 is identifiable by thenodes in the area that are in a range of the area that corresponds tothe communication range of the tracking device 400. After retrievingdata transmissions from the nodes that indicate when the nodes are inthe range of the tracking device, this information can be compared withthe mapping to determine the area where the tracking device is located.In embodiments, each area may correspond to a space wherein an uniquecombination of nodes is in the communication range of the area.

For example, in FIG. 5, nodes 514, 514A, 514B, and 514C are in the area517. If the program retrieves data indicating that nodes 514, 514A,514B, and 514C are in the communication range of the tracking device400, the program can reference the mapping and determine the trackingdevice is in the area 517.

In some embodiments, the nodes 510 may be configured to detect thesignal strength of the beacon signal 400A when it is received. Thesignal strength may vary at each node where the signal beacon isreceived, for example, nodes 514, 514A, 514B, and 514C. The programexecuted by the processor 520 may input the signal strengths received atthe nodes 514, 514A, 514B, and 514C into a multilateration algorithm todetermine the position of the tracking device 400 in the physical space20. The multilateration algorithm, in various embodiments, may also usethe known mapping of the nodes 514, 514A, 514B, and 514C in range of thetracking device 400 to determine the position of the tracking device400.

In some embodiments, the nodes 510, may be configured to detect theAngle of Arrival of the beacon signal at each node in range of thetracking device, for example, nodes 514, 514A, 514B, and 514C in FIG. 5.The program executed by the processor may input the Angle of Arrivaldata for each node 514, 514A, 514B, and 514C in range of the trackingdevice 400 into a triangulation algorithm to calculate the position ofthe tracking device 400 in the physical space 20. The triangulationalgorithm, in various embodiments, may use the known mapping of thenodes 514, 514A, 514B, and 514C in range of the tracking device 400 todetermine the position of the tracking device 400. The different ways todetermine the location of the tracking device may also be used invarious combinations with each other, in some embodiments, to improveaccuracy.

In some embodiments, the processor 520 may be in wireless communicationwith the node network 509.

In some embodiments, the tracking device 400 is continuously emitting abeacon signal 400A and it location can be determined in real time as itmoves through the network. In some embodiments, the tracking device 400may emit a beacon signal 400A periodically. In some embodiments, thetracking device 400 may emit a beacon signal 400A at a time determinedby a user.

It will be appreciated that tracking device 400 may be added to almostany other electronic device. Tracking devices may comprise wearablebands or buttons that people may transport through a space. Nodes of thenode network 509 may be configured with tracking devices so theirpositions can be updated in the mapping. Tracking devices could beattached to shopping carts or other equipment to track down missingitems or inventory.

In some embodiments, two or more nodes of the plurality of nodes 510comprise relay nodes 515, 522 each relay node 515, 522 being configuredto relay data transmissions to and from the other relay nodes. In FIG.5, nodes 514 and 515 may comprise relay nodes. Additional nodes in thenode network 509 may comprise relay nodes. Power consumption may belimited by utilizing a node network 9 wherein only some of the nodes arerelay nodes. In some embodiments, every node of the node network 509 maycomprise a relay node.

In some embodiments, one or more nodes of the plurality of nodescomprise memory nodes 514. Some nodes may be configured to be a relaynode and a memory node. In some embodiments each memory node 514 may beconfigured to store a historical data set identifying time periods whenthe memory node 514 is in the range of the tracking device 400. Thisdata can be retrieved by the processor 520 via the node network and theprocessor can execute a program to track the path 502 of the navigationdevice through the physical space 20 over time.

In some embodiments, data transmissions from the nodes of the pluralityof nodes 510 comprise the historical data sets of the one or more memorynodes 514 and the processor 520 is configured to execute the program toidentify the position of the tracking device 400 at one or more pasttimes by retrieving the data transmissions from the nodes of theplurality of nodes 510. In such embodiments, the tracking device 400 maybe tracked through the physical space 20. In some embodiments, memorynodes 514 may store historical data sets indefinitely so they may beretrieved whenever needed. And, in some embodiments the path 502 of thetracking device may be determined as a function of time based on thehistorical data sets.

In some embodiments, memory node 514 also stores information from nodes514A, 514B, and 514C that are neighbors with memory node 514. Forexample, in various embodiments, information stored in memory node 514indicates when nodes 514A, 514B and 514C are in range of the trackingdevice. In some embodiments, neighboring nodes comprise nodes 514A,514B, and 514C in a range of the memory node 514.

In some embodiments, the historical data set of each memory node 514identifies time periods when one or more nodes, for example, neighboringnodes 514A, 514B, 514C, of the plurality of nodes 510 that are in avicinity of the memory node 514 are in range of the tracking device 400.

In some embodiments the tracking system 500 may be combined with thenavigation system 300. In some embodiments the tracking device 400 mayfurther comprise a receiver 201 configured to receive a locationalsignal 302A emitted by a emitting node 302 of the plurality of nodes 10.In some embodiments the plurality of nodes 510 are configured to emitlocational signals 302A and also configured receive beacon signals 400A.And the tracking device 400 is configured to receive locational signals302A and emit beacon signals 400A.

The tracking device 400 may further comprise a memory 210 storing aprogram and a processor 208 in communication with the receiver 201 andconfigured to execute the navigation program to: access the mapping ofthe physical space 20, calculate a position of the tracking device 400in the physical space 20 from the locational signal 302A received by thetracking device 400, and determine a routing instruction from theposition of the tracking device 400 to a destination 308 based on theposition of the tracking device 400 and the mapping of the physicalspace 20.

In some embodiments, the navigation device 200 may further comprise atransmitter 403 configured to transmit a positional signal identifyingthe position of the navigation device 200 to the node network 9. In someembodiments the positional signal comprises the beacon signal 400A. Inembodiments, the nodes 10 of the node network 9 are configured toreceive the positional signal when in a reception range of thenavigation device 200.

In some embodiments the navigation system 300 further comprises atracking memory 518 storing a tracking program and a tracking processor520 in communication with the node network 9 and configured to executethe tracking program to identify the position of the navigational device200 by retrieving data transmissions from the plurality of nodes 10 thatindicate when the nodes of the plurality of nodes 10 are in the range ofthe navigational device 200.

Based on above, in various embodiments wherein the node network 509 ofthe tracking system comprises a BlueTooth Mesh network, the memory nodes514 may store the following information about nodes 514A, 514B, 514Cthat are neighbors: BlueTooth Device address of nodes 514A, 514B, 514Cthat are neighbors, whether the neighbor is a provisioned orunprovisioned device, the Universal Unique Identifier of unprovisionedneighbors, the network address of provisioned neighbor nodes (updatedonly if message received has a TTL=0), the Received Signal StrengthIndicator of the last message received from or by a neighbor node, andAngle of Arrival of the last message received from or by a neighbornode.

Advantageously, in accordance with embodiments of the present invention,existing indoor network and nodes may be able to be updated to supportthe features of this invention. No additional hardware may be needed butfor a firmware upgrade. Accordingly, embodiments of the presentinvention are cost effective. In addition, in embodiments comprisingBluetooth Mesh networks with TTL signals initialized at 0, there is nosignificant impact on the whole mesh network, as involved messages aregenerated with TTL=0 and therefore strictly confined to the neighbornodes (no relaying overhead). As it works on existing Bluetooth Meshnetwork, if and when required, information can be requested fromanywhere (control room) from participating nodes. This is useful whenthe system needs to be used for locating a moving node or human andasset in the network.

FIG. 6 illustrates a block diagram for a method 600 for navigationwithin a physical space comprising at step 602 emitting locationalsignals from a node network distributed throughout a physical space,wherein the locational signals identify the nodes of the node network.The method 600 further comprises at step 604 receiving one of thelocational signals at a navigation device emitted from a node of thenode network in a communication range of the navigation device; and atstep 606 calculating a spatial position of the navigational device froman identity of the node of the node network in the communication rangeof the navigation device. At step 608, the method 600 comprisesdetermining a routing instruction from the position of the navigationaldevice to a selected destination in the physical space.

In some embodiments, the method 600 further comprises providing therouting instructions through an interface of the navigational device.

In some embodiments, the method 600 further comprises updating thespatial position of the navigation device and the routing instruction asthe navigation device moves through the physical space.

In some embodiments of the method 600, the node network comprises a meshnetwork. In some embodiments of the method 600, the locational signalscomprise a time to live values that are set to zero. In someembodiments, the navigation device may determine that it is in range ofthe node that emitted a locational signal when it receives a locationalsignal with a TTL value=0. And, in some embodiments of the method 600,at least one of the nodes of the node network is located indoors.

FIG. 7 illustrates a block diagram for a method 700 for tracking adevice within a physical space comprising at step 702 mapping a nodenetwork within the physical space; at step 704 emitting a beacon signalfrom a tracking device at a location in the physical space; at step 706receiving the beacon at a plurality of nodes of the node network in acommunication range of the tracking device; at step 708 communicating anidentity of the nodes in the communication range of the tracking deviceto a processor; and at step 710 determining a spatial position of thetracking device by the processor from the identity of the nodes in therange of the tracking device.

In some embodiments, the method 700 further comprises updating thespatial position of the tracking device as the tracking device moverthrough the physical space.

In some embodiments of the method 700, the node network comprises a meshnetwork.

In some embodiments of the method 700, the beacon signal comprises atime to live value that is set to zero. In some embodiments, it may bedetermines that a node of the plurality of nodes is in the communicationrange of a tracking device when the receiving node it receives a beaconsignal with a TTL value=0.

In some embodiments of the method 700, at least one of the nodes of thenode network is located indoors.

Example embodiments of the invention are summarized here. Otherembodiments can also be understood from the entirety of thespecification as well as the claims filed herein.

Example 1. A navigation system includes a node network that includes aplurality of nodes distributed throughout a physical space. Theplurality of nodes is configured to emit a plurality of locationalsignals from a plurality of emitting nodes, where the plurality oflocational signals identifies the plurality of nodes. The navigationsystem further includes a map of the physical space including thelocations of the plurality of nodes. The navigation system furtherincludes a navigation device that includes a receiver configured toreceive a locational signal transmitted by a respective emitting node ofthe plurality of nodes in a communication range of the navigationdevice. The navigation device further includes a memory storing aprogram and a processor in communication with the receiver andconfigured to execute the program to access the map of the physicalspace, calculate a position of the navigation device in the physicalspace from the locational signal received by the navigation device, anddetermine a routing instruction from the position of the navigationdevice to a destination based on the position of the navigation deviceand the mapping of the physical space.

Example 2. The system of example 1, where the navigation device furtherincludes a user interface in communication with the processor andconfigured to provide the routing instruction.

Example 3. The system of one of examples 1 or 2, where the processor isalso configured to execute the program to update the position of thenavigation device and the routing instruction as the navigation devicemoves through the physical space.

Example 4. The system of one of examples 1 to 3, where the node networkincludes a mesh network.

Example 5. The system of one of examples 1 to 4, where the locationalsignals of the plurality of locational signals includes a time to livevalue that is set to zero.

Example 6. The system of one of examples 1 to 5, where the node networkprevents the locational signal of the plurality of locational signalsfrom being relayed by the plurality of nodes after the locational signalis emitted.

Example 7. The system of one of examples 1 to 6, where at least one ofthe nodes of the node network is located indoors.

Example 8. The system of one of examples 1 to 7, where each emittingnode of the node network emits a locational signal of the emitting nodethat identifies the emitting node, and where the locational signalreceived by the receiver includes the locational signal emitted by therespective emitting node.

Example 9. The system of one of examples 1 to 8, where the locationalsignal of each emitting node includes data indicating the position ofthe emitting node in the physical space.

Example 10. The system of one of examples 1 to 9, where the receiver isconfigured to receive additional locational signals of the plurality oflocational signals and where the position of the navigation device isfurther calculated from the identities of the emitting nodes identifiedby the additional locational signals.

Example 11. The system of one of examples 1 to 10, where the position ofthe navigation device is only calculated from locational signalsincluding a time to live value set to 0.

Example 12. The system of one of examples 1 to 11, where the navigationdevice is configured to detect an angle of arrival of the locationalsignal and an angle of arrival for each of the additional locationalsignals and where the program utilizes a triangulation algorithm tocalculate the position of the navigation device based at least on theangle of arrival of the locational signal and the angle of arrival ofeach the additional locational signals.

Example 13. The system for one of examples 1 to 12, where the navigationdevice is configured to detect a signal strength of the locationalsignal and a signal strengths of each of the additional locationalsignals and where the program utilizes a multilateration algorithm tocalculate the position of the navigation device based at least on thesignal strength of the locational signal and the signal strengths ofeach of the additional locational signals.

Example 14. The system of one of examples 1 to 13, where the emittingnodes of the node network continuously emit locational signals.

Example 15. The system of one of examples 1 to 14, where the nodes ofthe node network are configured for node to node communication.

Example 16. The system of one of examples 1 to 15, where the navigationdevice further includes a transmitter configured to transmit apositional signal identifying the position of the navigation device andthe nodes of the node network are configured to receive the positionalsignal when in a reception range of the navigation device.

Example 17. The system of one of examples 1 to 16, further including: atracking memory storing a tracking program; and a tracking processor incommunication with the node network and configured to execute thetracking program to identify the position of the navigational device byretrieving data transmissions from the plurality of nodes that indicatewhen the nodes of the plurality of nodes are in the range of thenavigational device.

Example 18. A system for tracking a device in a physical space includesa tracking device disposed at a position in the physical space. Thetracking device includes a transmitter configured to transmit a beaconsignal that identifies the tracking device. The system includes a nodenetwork including a plurality of nodes, where the nodes of the pluralityof nodes are configured to receive the beacon signal when in acommunication range of the tracking device. The system also includes amap of the physical space including locations of the nodes of theplurality of nodes. The tracking device further includes a memorystoring a program and a processor in communication with the node networkand the memory. The processor is configured to execute the program toidentify the position of the tracking device by retrieving datatransmissions from the plurality of nodes that indicate when the nodesof the plurality of nodes are in the range of the tracking device.

Example 19. The system of example 18, where two or more nodes of theplurality of nodes include relay nodes, each relay node being configuredto relay data transmissions to and from the other relay nodes.

Example 20. The system of one of examples 18 or 19, where nodes of theplurality of nodes include memory nodes, each memory node beingconfigured to store a historical data set identifying time periods whenthe memory node is in the range of the tracking device.

Example 21. The system of one of examples 18 to 20, where datatransmissions from the nodes of the plurality of nodes include thehistorical data sets of the plurality of memory nodes and the processoris configured to execute the program to identify the position of thetracking device at past times by retrieving data transmissions from thenodes of the plurality of nodes.

Example 22. The system of one of examples 18 to 21, where the historicaldata set of each memory node identifies time periods when nodes of theplurality of nodes that are in a vicinity of the memory node are in thecommunication range of the tracking device.

Example 23. The system of one of examples 18 to 22, where the nodenetwork includes a mesh network.

Example 24. The system of one of examples 18 to 23, where the beaconsignal includes a time to live value that is set to zero.

Example 25. The system of one of examples 18 to 24, where the nodenetwork prevents the beacon signal from being relayed by the pluralityof nodes after the beacon signal is transmitted by the tracking device.

Example 26. The system of one of examples 18 to 25, where the nodes ofthe plurality of nodes are configured to detect an angle of arrival ofthe beacon signal at each node in the communication range and where theprogram utilizes a triangulation algorithm to calculate the position ofthe tracking device based at least on the angle of arrival of the beaconsignal at each node in the communication range.

Example 27. The system for one of examples 18 to 26, where the nodes ofthe plurality of nodes are configured to detect a signal strength of thebeacon signal at each node in the communication range and where theprogram utilizes a multilateration algorithm to calculate the positionof the tracking device based at least on the signal strength of thebeacon signal at each node in the communication range.

Example 28. The system of one of examples 18 to 27, where the trackingdevice further includes: a receiver configured to receive a locationalsignal emitted by a respective emitting node of the plurality of nodes;a tracking memory storing a tracking program; and a tracking processorin communication with the receiver and configured to execute thetracking program to access the mapping of the physical space, calculatethe position of the tracking device in the physical space from thelocational signal received by the tracking device, and determine arouting instruction from the position of the tracking device to adestination based on the position of the tracking device and the mappingof the physical space.

Example 29. A method for navigation within a physical space includesemitting locational signals from a node network distributed throughout aphysical space, where the locational signals identify the nodes of thenode network. The method further includes receiving one of thelocational signals at a navigation device emitted from a node of thenode network in a communication range of the navigation device. Themethod further includes calculating a spatial position of thenavigational device from an identity of the node of the node network inthe communication range of the navigation device. The method furtherincludes determining a routing instruction from the position of thenavigational device to a selected destination in the physical space.

Example 30. The method of example 29, further including providing therouting instructions through an interface of the navigational device.

Example 31. The method of one of examples 29 or 30, further includingupdating the spatial position of the navigation device and the routinginstruction as the navigation device moves through the physical space.

Example 32. The method of one of examples 29 to 31, where the nodenetwork includes a mesh network.

Example 33. The method of one of examples 29 to 32, where the locationalsignals include time to live values that are set to zero.

Example 34. The method of one of examples 29 to 33, where at least oneof the nodes of the node network is located indoors.

Example 35. The method of one of examples 29 to 34, further includingreceiving additional locational signals at the navigation device andsensing an angle of arrival of the one of the locational signals and anangle of arrival of each of the additional signals, and wherecalculating a spatial position of the navigation device further includestriangulating the position of the navigation device at least from theangle of arrival of the one of the locational signals and the angle ofarrival of each of the additional signals.

Example 36. The method of one of examples 29 to 35, further includingreceiving additional locational signals at the navigation device andsensing a signal strength of the one of the locational signals andsensing a signal strength of each of the additional signals and wherecalculating a spatial position of the navigation device further includesmultilateration of the position of the navigation device at least fromthe signal strength of the one of the locational signals and the signalstrength of each of the additional signals.

Example 37. A method for tracking a device within a physical spaceincluding: mapping a node network within the physical space; emitting abeacon signal from a tracking device at a location in the physicalspace; receiving the beacon signal at a plurality of nodes of the nodenetwork in a communication range of the tracking device; communicatingan identity of the nodes in the communication range of the trackingdevice to a processor; and determining a spatial position of thetracking device by the processor from the identity of the nodes in therange of the tracking device.

Example 38. The method of example 37, further including updating thespatial position of the tracking device as the tracking device movesthrough the physical space.

Example 39. The method of one of examples 37 or 38, where the nodenetwork includes a mesh network.

Example 40. The method of one of examples 37 to 39, where the beaconsignal includes a time to live value that is set to zero.

Example 41. The method of one of examples 37 to 40, where at least oneof the nodes of the node network is located indoors.

Example 42. The method of one of examples 37 to 40, further includingsensing an angle of arrival of the beacon signal at each of theplurality of nodes and where determining a spatial position of thetracking device further includes triangulating the position of thetracking device at least from the angle of arrival of the beacon signalat each of the plurality of nodes.

Example 43. The method of one of examples 37 to 42, further includingsensing an signal strength of the beacon signal at each of the pluralityof nodes and where determining a spatial position of the tracking devicefurther includes multilateration of the position of the tracking deviceat least from the signal strength of the beacon signal at each of theplurality of nodes.

While this invention has been described with reference to illustrativeembodiments, this description is not intended to be construed in alimiting sense. Various modifications and combinations of theillustrative embodiments, as well as other embodiments of the invention,will be apparent to persons skilled in the art upon reference to thedescription. It is therefore intended that the appended claims encompassany such modifications or embodiments.

1. A navigation system comprising: a mesh network comprising a pluralityof nodes distributed throughout a physical space, the plurality of nodesbeing configured to emit locational signals comprising a time to livevalue initialized at zero; a navigation device comprising: a receiverconfigured to receive locational signals; a memory storing a program;and a processor in communication with the receiver and configured toexecute the program to access a map of the physical space comprisinglocations of the plurality of nodes, calculate a position of thenavigation device in the physical space from locational signal receivedby the navigation device, and determine a routing instruction from theposition of the navigation device to a destination based on the positionof the navigation device and the map of the physical space.
 2. Thenavigation system of claim 1, wherein the navigation device furthercomprises a user interface in communication with the processor andconfigured to provide the routing instruction.
 3. The navigation systemof claim 1, wherein the processor is also configured to execute theprogram to update the position of the navigation device and the routinginstruction as the navigation device moves through the physical space.4. The navigation system of claim 1, wherein the mesh network preventslocational signals from being relayed by the plurality of nodes afterlocational signals are emitted because the time to live value is set tozero of the locational signals is set to zero.
 5. The navigation systemof claim 1, wherein locational signals comprises data indicating aposition of a node from where they were emitted.
 6. The navigationsystem of claim 1, wherein the navigation device further comprises atransmitter configured to transmit a positional signal identifying theposition of the navigation device and the plurality of nodes areconfigured to receive the positional signal when in a reception range ofthe navigation device.
 7. The navigation system of claim 1, furthercomprising: a tracking memory storing a tracking program; and a trackingprocessor in communication with the mesh network and configured toexecute the tracking program to identify the position of thenavigational device by retrieving data transmissions from the pluralityof nodes that indicate when the nodes of the plurality of nodes havebeen in a range of the navigational device.
 8. A system for tracking adevice in a physical space comprising: a tracking device disposed at aposition in the physical space, the tracking device comprising atransmitter configured to transmit a beacon signal that identifies thetracking device, the beacon signal comprising a time to live valueinitialized at zero; a mesh network comprising a plurality of nodesdistributed throughout the physical space, the nodes of the plurality ofnodes being configured to receive the beacon signal; a memory storing aprogram; and a processor in communication with the mesh network and thememory, the processor being configured to execute the program toidentify the position of the tracking device by retrieving datatransmissions from the plurality of nodes that indicate when the nodesof the plurality of nodes have been in a communication range of thetracking device.
 9. The system of claim 8, wherein the plurality ofnodes comprises a plurality of memory nodes, each memory node beingconfigured to store a historical data set identifying time periods whenthe memory node has been in the communication range of the trackingdevice.
 10. The system of claim 9, wherein data transmissions retrievedby the processor comprise the historical data sets of the plurality ofmemory nodes and the processor is configured to execute the program toidentify the position of the tracking device at in the past byretrieving data transmissions from the nodes of the plurality of nodes.11. The system of claim 9, wherein the historical data set of eachmemory node identifies time periods when nodes of the plurality of nodesthat are in a vicinity of that memory node are in the communicationrange of the tracking device.
 12. The system of claim 8, wherein themesh network prevents the beacon signal from being relayed by theplurality of nodes after the beacon signal is transmitted by thetracking device.
 13. The system of claim 8, wherein the tracking devicefurther comprises: a receiver configured to receive locational signalsemitted by the plurality of nodes; a navigation memory storing atracking program; and a navigation processor in communication with thereceiver and configured to execute a navigation program to access a mapof the physical space comprising locations of the plurality of nodes,calculate the position of the tracking device in the physical space fromthe locational signal received by the tracking device, and determine arouting instruction from the position of the tracking device to adestination based on the position of the tracking device and the map ofthe physical space.
 14. A method for navigation within a physical spacecomprising: emitting locational signals from a plurality of nodes of amesh network, the locational signals comprising time to live valuesinitialized at zero, wherein the locational signals identify the nodesof the plurality of nodes; receiving locational signals at a navigationdevice; calculating a spatial position of the navigational device fromthe locational signals and a map of locations of the plurality of nodes;and determining a routing instruction from the spatial position of thenavigational device to a selected destination in the physical space. 15.The method of claim 14, further comprising providing the routinginstruction through an interface of the navigational device.
 16. Themethod of claim 14, further comprising updating the spatial position ofthe navigation device and the routing instruction as the navigationdevice moves through the physical space.
 17. The method of claim 14,further comprising tracking the spatial position of the navigationdevice in the physical space as it moves through the physical space. 18.A method for tracking a device within a physical space comprising:emitting a beacon signal from a tracking device at a location in thephysical space, the beacon signal comprising a time to live valueinitialized at zero; receiving the beacon signal at one or more nodes ofa plurality of nodes of a mesh network within the physical space;communicating an identity of the one or more nodes to a processor; anddetermining a spatial position of the tracking device by the processorfrom the identity of the one or more nodes and a map of the meshnetwork.
 19. The method of claim 18, further comprising updating thespatial position of the tracking device as the tracking device movesthrough the physical space.
 20. The method of claim 19, furthercomprising providing a routing instruction to a destination based on thespatial position of the tracking device and the map.